Particle in a box- Application of Schrodinger wave equationRawat DA Greatt
The document summarizes key concepts from quantum chemistry, including:
1) It introduces the historical development of quantum mechanics from classical mechanics and discusses how quantum theory was needed to describe atomic and subatomic phenomena.
2) It then summarizes the particle-like and wave-like properties of light and matter and introduces the Schrodinger equation.
3) The document concludes by presenting the particle-in-a-box model and explaining how solving the Schrodinger equation for this system shows that a particle's energy is quantized into discrete energy levels when confined in a box.
Physics concepts like chromatography, electrophoresis, spectroscopy, centrifugation, and microscopy are important tools in biology. Chromatography separates molecules in a mixture using mobile and stationary phases. Electrophoresis separates charged particles like DNA, RNA, or proteins using an electric field. Spectroscopy analyzes properties of materials like proteins and lipids using radiation. Centrifugation separates particles by density using centrifugal force. Microscopy magnifies cells and structures for analysis using principles of magnification, resolution, and focusing. Biophysics integrates physics and biology to better understand molecular mechanisms of life.
Prokaryotic cells have several structures that allow them to move, adhere to surfaces, and protect themselves. These structures include flagella, pili, and a cell envelope. The cell envelope is composed of a cell wall and cell membrane. The cell wall provides structure and protection, and its composition differs between Gram-positive and Gram-negative bacteria. Internally, prokaryotic cells contain a single loop of DNA, ribosomes, and inclusion bodies that store nutrients.
The document discusses cell theory and the history of cell discovery. It explains that Robert Hooke first observed cells in 1665 using a microscope. Anton van Leeuwenhoek later discovered single-celled organisms. In the 1830s-1840s, scientists including Matthias Schleiden, Theodor Schwann, and Rudolf Virchow developed cell theory, which states that all organisms are composed of cells, cells are the basic unit of life, and new cells are produced from existing cells. The document also describes key differences between prokaryotic and eukaryotic cells.
The document discusses the history and key figures in the discovery and establishment of the cell theory. It notes that cells were first observed in the 1600s using early microscopes. Key contributors included Hooke, who first observed cells in cork in 1665 and coined the term "cell", and van Leeuwenhoek who observed single-celled organisms in pond water in the 1670s. In the 1830s, Schleiden and Schwann established that plants and animals are composed of cells, respectively, and Schwann proposed the original cell theory. Virchow later expanded on this in 1858 by stating that all cells come from pre-existing cells.
Wave-particle duality proposes that all particles exhibit both wave and particle properties. Light was originally thought to consist solely of waves or particles, but through the work of Planck, Einstein, Bohr and others, it is now understood that particles also have a wave nature, and vice versa. This phenomenon of wave-particle duality is a fundamental principle of quantum physics where matter and light behave as both waves and particles depending on the experimental conditions.
Quantum theory provides a framework to understand phenomena at the atomic scale that cannot be explained by classical physics. It proposes that energy is emitted and absorbed in discrete units called quanta. This explains observations like the photoelectric effect where electrons are only ejected above a threshold frequency. Light behaves as both a wave and particle - a photon. Similarly, matter exhibits wave-particle duality as demonstrated by electron diffraction. At the quantum level, only probabilities, not definite values, can be predicted. Quantum mechanics is applied to describe atomic structure and spectra.
Particle in a box- Application of Schrodinger wave equationRawat DA Greatt
The document summarizes key concepts from quantum chemistry, including:
1) It introduces the historical development of quantum mechanics from classical mechanics and discusses how quantum theory was needed to describe atomic and subatomic phenomena.
2) It then summarizes the particle-like and wave-like properties of light and matter and introduces the Schrodinger equation.
3) The document concludes by presenting the particle-in-a-box model and explaining how solving the Schrodinger equation for this system shows that a particle's energy is quantized into discrete energy levels when confined in a box.
Physics concepts like chromatography, electrophoresis, spectroscopy, centrifugation, and microscopy are important tools in biology. Chromatography separates molecules in a mixture using mobile and stationary phases. Electrophoresis separates charged particles like DNA, RNA, or proteins using an electric field. Spectroscopy analyzes properties of materials like proteins and lipids using radiation. Centrifugation separates particles by density using centrifugal force. Microscopy magnifies cells and structures for analysis using principles of magnification, resolution, and focusing. Biophysics integrates physics and biology to better understand molecular mechanisms of life.
Prokaryotic cells have several structures that allow them to move, adhere to surfaces, and protect themselves. These structures include flagella, pili, and a cell envelope. The cell envelope is composed of a cell wall and cell membrane. The cell wall provides structure and protection, and its composition differs between Gram-positive and Gram-negative bacteria. Internally, prokaryotic cells contain a single loop of DNA, ribosomes, and inclusion bodies that store nutrients.
The document discusses cell theory and the history of cell discovery. It explains that Robert Hooke first observed cells in 1665 using a microscope. Anton van Leeuwenhoek later discovered single-celled organisms. In the 1830s-1840s, scientists including Matthias Schleiden, Theodor Schwann, and Rudolf Virchow developed cell theory, which states that all organisms are composed of cells, cells are the basic unit of life, and new cells are produced from existing cells. The document also describes key differences between prokaryotic and eukaryotic cells.
The document discusses the history and key figures in the discovery and establishment of the cell theory. It notes that cells were first observed in the 1600s using early microscopes. Key contributors included Hooke, who first observed cells in cork in 1665 and coined the term "cell", and van Leeuwenhoek who observed single-celled organisms in pond water in the 1670s. In the 1830s, Schleiden and Schwann established that plants and animals are composed of cells, respectively, and Schwann proposed the original cell theory. Virchow later expanded on this in 1858 by stating that all cells come from pre-existing cells.
Wave-particle duality proposes that all particles exhibit both wave and particle properties. Light was originally thought to consist solely of waves or particles, but through the work of Planck, Einstein, Bohr and others, it is now understood that particles also have a wave nature, and vice versa. This phenomenon of wave-particle duality is a fundamental principle of quantum physics where matter and light behave as both waves and particles depending on the experimental conditions.
Quantum theory provides a framework to understand phenomena at the atomic scale that cannot be explained by classical physics. It proposes that energy is emitted and absorbed in discrete units called quanta. This explains observations like the photoelectric effect where electrons are only ejected above a threshold frequency. Light behaves as both a wave and particle - a photon. Similarly, matter exhibits wave-particle duality as demonstrated by electron diffraction. At the quantum level, only probabilities, not definite values, can be predicted. Quantum mechanics is applied to describe atomic structure and spectra.
This document provides an overview and introduction to a physics course. It outlines keys to success such as attending class, taking notes, and treating schoolwork like a job. It then defines physics as the study of interactions between matter and energy and lists topics that will be covered including mechanics, electricity, waves, optics, thermodynamics, and modern physics. It provides guidance on homework, evaluations, and concludes with an activity where students will analyze pictures in groups and identify which areas of physics they illustrate.
Einstein’s Theories of Relativity revolutionized how Today’s Scientific world thinks about Space, Time, Mass, Energy and Gravity. This is purely an imaginative Science that worked in the Laboratory of Einstein's Brain..
origin of quantum physics -
Inadequacy of classical mechanics and birth of QUANTUM PHYSICS
ref: Quantum mechanics: concepts and applications, N. Zettili
Quantum mechanics describes the behavior of matter and light on the atomic and subatomic scale. Some key points of the quantum mechanics view are that particles can exhibit both wave-like and particle-like properties, their behavior is probabilistic rather than definite, and some properties like position and momentum cannot be known simultaneously with complete precision due to the Heisenberg uncertainty principle. Quantum mechanics has successfully explained various phenomena that classical physics could not and led to important technologies like lasers, MRI machines, and semiconductor devices.
1. Quantum mechanics began with Max Planck's paper in 1900 explaining black body radiation. It extends physics to small dimensions and includes classical laws as special cases.
2. Photoelectric effect shows that light behaves as particles called photons. Einstein's equation explained it using the photon energy.
3. Compton scattering showed that photons can collide with and transfer energy to electrons. The Compton wavelength was derived from this.
Introduction to physics--Branches of Physics--Importance of physicsKhanSaif2
Physics is the study of fundamental laws governing natural phenomena. It deals with the most basic aspects of nature, including force, motion, heat, sound, matter, electricity, magnetism, and light. Physics seeks to discover the basic rules that describe physical phenomena through observation and experimentation. Some key ideas presented are:
- Physics can be divided into classical and modern physics, with classical emerging before the 19th century covering mechanics, thermodynamics, electromagnetism, and optics, while modern physics emerged after covering atomic, nuclear, and quantum physics.
- Important branches include mechanics, wave physics, thermodynamics, electromagnetism, optics, atomic physics, nuclear physics, and quantum mechanics.
-
This document summarizes Louis de Broglie's hypothesis of wave-particle duality and its applications. It discusses de Broglie's proposal that particles have wave-like properties with a wavelength given by Planck's constant divided by momentum. The photoelectric effect and Compton effect provide evidence of wave and particle behavior of light and electrons. Wave-particle duality is exploited in technologies like electron microscopy and neutron diffraction to examine structures smaller than visible light wavelengths. While useful, wave-particle duality does not fully explain quantum phenomena like the Heisenberg uncertainty principle.
1. The cell theory states that the cell is the basic unit of life, all living things are made of cells, and cells come from pre-existing cells.
2. Anton van Leeuwenhoek invented the first microscope and was the first to observe bacteria and protists. Matthais Schleiden and Theodor Schwann contributed to the cell theory by stating that plants and animals are made of cells, respectively.
3. Rudolph Virchow completed the cell theory by discovering that cells can only arise from pre-existing cells.
Electromagnetic waves are formed by vibrating electric charges and can transfer energy through space without matter. They are transverse waves consisting of oscillating electric and magnetic fields. Electromagnetic waves can behave as either waves or particles called photons, with higher frequency waves having shorter wavelengths. The entire range of electromagnetic wave frequencies is called the electromagnetic spectrum.
The document discusses particle accelerators and nuclear physics. It provides definitions of particle accelerators and describes their basic working principle of using electromagnetic fields to accelerate charged particles. It discusses different types of particle accelerators like linear accelerators, cyclotrons, synchrotrons and their components and working. The largest particle accelerators in the world, like the LHC and RHIC, are mentioned. Applications of particle accelerators discussed include uses in medicine, industry, DNA research and treating cancer.
The document summarizes key aspects of Einstein's special theory of relativity, including:
1) It showed that Newton's ideas of absolute space and time were incorrect and implied that matter and energy are interconvertible.
2) It established two postulates - the laws of physics apply in all inertial frames, and the speed of light is constant in all frames.
3) This leads to effects like time dilation and length contraction, as measurements of space and time differ for observers in different inertial frames moving relative to one another.
The document discusses the Pauli Exclusion Principle and its importance in the periodic table. It explains that the principle states that no two electrons in an atom can have the same set of quantum numbers, and electrons must have opposite spins when occupying the same orbital. This principle allows electrons to be arranged in shells and is crucial for determining an element's chemical properties and for constructing the periodic table by blocks.
The document summarizes the history and development of cell theory. It discusses key figures such as Hooke, who first observed and named cells in 1665; Van Leeuwenhoek, who observed the first living cells in 1683; and Schleiden, Schwann, and Virchow, who developed the three principles of cell theory - that all living things are made of cells, cells are the basic unit of life, and new cells are produced from existing cells. The document also describes the basic structures and differences between prokaryotic and eukaryotic cell types.
This document discusses the uncertainty principle as stated by Werner Heisenberg in 1927. It provides Heisenberg's background and contributions to physics. The principle states that the momentum and position of a particle cannot be simultaneously measured with perfect precision due to inherent uncertainties. There is a minimum for the product of the uncertainties in these two measurements. The document explains this concept and provides the formula for the uncertainty principle.
The document discusses the wave properties of particles. Some key points:
1) Louis de Broglie hypothesized in 1924 that matter has an associated wave-like nature with a wavelength given by Planck's constant divided by momentum.
2) A particle can be represented as a localized "wave packet" resulting from the interference and superposition of multiple waves with slightly different wavelengths and frequencies.
3) Davisson and Germer's electron diffraction experiment in 1927 provided direct evidence of the wave nature of electrons and supported de Broglie's hypothesis by measuring electron wavelengths matching those expected.
The document summarizes the Geiger-Müller counter, which detects ionizing radiation using a Geiger-Müller tube. It consists of the tube filled with an inert gas at low pressure and high voltage applied. When radiation enters the tube, it causes ionization which produces an electric current as electrons are attracted to the high voltage electrode. This creates a cascade of additional ionization, allowing the radiation to be detected. Geiger counters are used to measure radiation levels for applications like radiation dosimetry and nuclear industry. They exist in different designs depending on the type of radiation being detected.
Physics is the study of matter, energy, and their interaction. It has two main branches: classical physics which studies mechanics, thermodynamics, and electromagnetism, and modern physics which studies atomic and nuclear physics and quantum physics. Measurement is the process of comparing quantities using standard units like the metric system which defines fundamental units like meters, kilograms, and seconds. Conversion between units can be done using conversion factors in a chain-link method.
- Nuclear fission involves splitting large nuclei like uranium, releasing energy. Fusion joins light nuclei like hydrogen, also releasing energy.
- Fission is used in nuclear power plants and bombs. Fusion powers stars and could be an energy source on Earth if containment and high temperature issues are solved.
- The binding energy curve shows that mid-sized nuclei are most stable, and that fission and fusion involving less stable nuclei release energy.
This document is a chapter on cell structure and function that covers:
1) The history of cell biology including the scientists who discovered cells and the development of the cell theory.
2) An introduction to cells explaining cell diversity, size, shape, basic parts, and the differences between prokaryotic and eukaryotic cells.
3) Cell organelles and features such as the plasma membrane, nucleus, mitochondria, ER, Golgi apparatus, cytoskeleton, and how they function.
4) Unique features of plant cells including cell walls, central vacuoles, and plastids.
Cranial Laser Reflex Technique: Healthcare for GeniusesNicholas Wise
Cranial Laser Reflex Technique is an exciting new development in natural pain relief and functional improvement. This stand-alone method allows a practitioner with any cold laser to be able to reduce someone's musculoskeletal pain with amazing speed. This condensed version of Dr. Nick Wise's recent lecture gives the scientific basis of CLRT.
This document provides an overview and introduction to a physics course. It outlines keys to success such as attending class, taking notes, and treating schoolwork like a job. It then defines physics as the study of interactions between matter and energy and lists topics that will be covered including mechanics, electricity, waves, optics, thermodynamics, and modern physics. It provides guidance on homework, evaluations, and concludes with an activity where students will analyze pictures in groups and identify which areas of physics they illustrate.
Einstein’s Theories of Relativity revolutionized how Today’s Scientific world thinks about Space, Time, Mass, Energy and Gravity. This is purely an imaginative Science that worked in the Laboratory of Einstein's Brain..
origin of quantum physics -
Inadequacy of classical mechanics and birth of QUANTUM PHYSICS
ref: Quantum mechanics: concepts and applications, N. Zettili
Quantum mechanics describes the behavior of matter and light on the atomic and subatomic scale. Some key points of the quantum mechanics view are that particles can exhibit both wave-like and particle-like properties, their behavior is probabilistic rather than definite, and some properties like position and momentum cannot be known simultaneously with complete precision due to the Heisenberg uncertainty principle. Quantum mechanics has successfully explained various phenomena that classical physics could not and led to important technologies like lasers, MRI machines, and semiconductor devices.
1. Quantum mechanics began with Max Planck's paper in 1900 explaining black body radiation. It extends physics to small dimensions and includes classical laws as special cases.
2. Photoelectric effect shows that light behaves as particles called photons. Einstein's equation explained it using the photon energy.
3. Compton scattering showed that photons can collide with and transfer energy to electrons. The Compton wavelength was derived from this.
Introduction to physics--Branches of Physics--Importance of physicsKhanSaif2
Physics is the study of fundamental laws governing natural phenomena. It deals with the most basic aspects of nature, including force, motion, heat, sound, matter, electricity, magnetism, and light. Physics seeks to discover the basic rules that describe physical phenomena through observation and experimentation. Some key ideas presented are:
- Physics can be divided into classical and modern physics, with classical emerging before the 19th century covering mechanics, thermodynamics, electromagnetism, and optics, while modern physics emerged after covering atomic, nuclear, and quantum physics.
- Important branches include mechanics, wave physics, thermodynamics, electromagnetism, optics, atomic physics, nuclear physics, and quantum mechanics.
-
This document summarizes Louis de Broglie's hypothesis of wave-particle duality and its applications. It discusses de Broglie's proposal that particles have wave-like properties with a wavelength given by Planck's constant divided by momentum. The photoelectric effect and Compton effect provide evidence of wave and particle behavior of light and electrons. Wave-particle duality is exploited in technologies like electron microscopy and neutron diffraction to examine structures smaller than visible light wavelengths. While useful, wave-particle duality does not fully explain quantum phenomena like the Heisenberg uncertainty principle.
1. The cell theory states that the cell is the basic unit of life, all living things are made of cells, and cells come from pre-existing cells.
2. Anton van Leeuwenhoek invented the first microscope and was the first to observe bacteria and protists. Matthais Schleiden and Theodor Schwann contributed to the cell theory by stating that plants and animals are made of cells, respectively.
3. Rudolph Virchow completed the cell theory by discovering that cells can only arise from pre-existing cells.
Electromagnetic waves are formed by vibrating electric charges and can transfer energy through space without matter. They are transverse waves consisting of oscillating electric and magnetic fields. Electromagnetic waves can behave as either waves or particles called photons, with higher frequency waves having shorter wavelengths. The entire range of electromagnetic wave frequencies is called the electromagnetic spectrum.
The document discusses particle accelerators and nuclear physics. It provides definitions of particle accelerators and describes their basic working principle of using electromagnetic fields to accelerate charged particles. It discusses different types of particle accelerators like linear accelerators, cyclotrons, synchrotrons and their components and working. The largest particle accelerators in the world, like the LHC and RHIC, are mentioned. Applications of particle accelerators discussed include uses in medicine, industry, DNA research and treating cancer.
The document summarizes key aspects of Einstein's special theory of relativity, including:
1) It showed that Newton's ideas of absolute space and time were incorrect and implied that matter and energy are interconvertible.
2) It established two postulates - the laws of physics apply in all inertial frames, and the speed of light is constant in all frames.
3) This leads to effects like time dilation and length contraction, as measurements of space and time differ for observers in different inertial frames moving relative to one another.
The document discusses the Pauli Exclusion Principle and its importance in the periodic table. It explains that the principle states that no two electrons in an atom can have the same set of quantum numbers, and electrons must have opposite spins when occupying the same orbital. This principle allows electrons to be arranged in shells and is crucial for determining an element's chemical properties and for constructing the periodic table by blocks.
The document summarizes the history and development of cell theory. It discusses key figures such as Hooke, who first observed and named cells in 1665; Van Leeuwenhoek, who observed the first living cells in 1683; and Schleiden, Schwann, and Virchow, who developed the three principles of cell theory - that all living things are made of cells, cells are the basic unit of life, and new cells are produced from existing cells. The document also describes the basic structures and differences between prokaryotic and eukaryotic cell types.
This document discusses the uncertainty principle as stated by Werner Heisenberg in 1927. It provides Heisenberg's background and contributions to physics. The principle states that the momentum and position of a particle cannot be simultaneously measured with perfect precision due to inherent uncertainties. There is a minimum for the product of the uncertainties in these two measurements. The document explains this concept and provides the formula for the uncertainty principle.
The document discusses the wave properties of particles. Some key points:
1) Louis de Broglie hypothesized in 1924 that matter has an associated wave-like nature with a wavelength given by Planck's constant divided by momentum.
2) A particle can be represented as a localized "wave packet" resulting from the interference and superposition of multiple waves with slightly different wavelengths and frequencies.
3) Davisson and Germer's electron diffraction experiment in 1927 provided direct evidence of the wave nature of electrons and supported de Broglie's hypothesis by measuring electron wavelengths matching those expected.
The document summarizes the Geiger-Müller counter, which detects ionizing radiation using a Geiger-Müller tube. It consists of the tube filled with an inert gas at low pressure and high voltage applied. When radiation enters the tube, it causes ionization which produces an electric current as electrons are attracted to the high voltage electrode. This creates a cascade of additional ionization, allowing the radiation to be detected. Geiger counters are used to measure radiation levels for applications like radiation dosimetry and nuclear industry. They exist in different designs depending on the type of radiation being detected.
Physics is the study of matter, energy, and their interaction. It has two main branches: classical physics which studies mechanics, thermodynamics, and electromagnetism, and modern physics which studies atomic and nuclear physics and quantum physics. Measurement is the process of comparing quantities using standard units like the metric system which defines fundamental units like meters, kilograms, and seconds. Conversion between units can be done using conversion factors in a chain-link method.
- Nuclear fission involves splitting large nuclei like uranium, releasing energy. Fusion joins light nuclei like hydrogen, also releasing energy.
- Fission is used in nuclear power plants and bombs. Fusion powers stars and could be an energy source on Earth if containment and high temperature issues are solved.
- The binding energy curve shows that mid-sized nuclei are most stable, and that fission and fusion involving less stable nuclei release energy.
This document is a chapter on cell structure and function that covers:
1) The history of cell biology including the scientists who discovered cells and the development of the cell theory.
2) An introduction to cells explaining cell diversity, size, shape, basic parts, and the differences between prokaryotic and eukaryotic cells.
3) Cell organelles and features such as the plasma membrane, nucleus, mitochondria, ER, Golgi apparatus, cytoskeleton, and how they function.
4) Unique features of plant cells including cell walls, central vacuoles, and plastids.
Cranial Laser Reflex Technique: Healthcare for GeniusesNicholas Wise
Cranial Laser Reflex Technique is an exciting new development in natural pain relief and functional improvement. This stand-alone method allows a practitioner with any cold laser to be able to reduce someone's musculoskeletal pain with amazing speed. This condensed version of Dr. Nick Wise's recent lecture gives the scientific basis of CLRT.
Holographic patches use frequencies extracted from active ingredients and stored as holograms to influence the body's energetic field and enhance cellular communication. When applied topically, the patches relay these frequencies which can help restore balance and aid healing similar to nutrients or medications. The technology builds on pioneering work by Nikola Tesla and others demonstrating that different frequencies affect the body and can be used therapeutically.
The use of magnetism in medicine is recorded in the history of most civilizations. The first usage is noted in Chinese writings (approximately 2000 B.C.), referencing the use of magnetism in conjunction with acupuncture. Cleopatra is said to have worn a lodestone on her forehead to prevent aging.
1. Quantum science provides tools for studying human group behavior and the interactions between parts of the human body, mind, and emotions.
2. The Quantum Life App aims to balance the dynamic state of the human body using harmonic frequencies to analyze and provide balancing to individuals.
3. Our health depends on the body's proper processing of information and energy from its interconnection with the larger universe, governed by quantum electrodynamics and energetic fields.
1. Quantum science can be applied to study human group behavior, interactions between parts of the body, mind and emotions, and complex systems in general.
2. The Quantum Life APP balances the dynamic state of the human body using harmonic frequencies to analyze and provide balancing to the individual.
3. Distortions in the holographic human body field can affect health, and correcting such distortions can help return the body to homeostasis.
Chapter 4: The Electromagnetic Spectrum in ManDouglas Arndt
“In the light of present knowledge, it can be seen that disease starts primarily at the atomic level when the proper release and utilization of energy are interfered with and proper control of biological activities is disturbed by malpositioned molecules.” R.W. Walker in Energy, Matter and Life
Introduction
What is a frequency?
Can the frequency of an item be changed?
Neurophysiology
Accepted electro based evaluations and therapies
Acupuncture points and meridians
Electroacupuncture
Electromagnetic fields
Chakras, connecting us to all
Evaluating the electromagnetic field
What is kinesiology?
Why does kinesiology work?
What is the power of induction?
Application of kinesiology
Summary points for human electromagnetics
Auras – layers of the electromagnetic field
Why know about the electromagnetic field?
Colors of the electromagnetic field
How to see electromagnetic fields with the human eye
Chakras, connecting us to all
This document introduces the concept of the human biofield or energy field that underlies the physical body. Researchers from various disciplines believe that we are quantum beings influenced by quantum fields and forces. The human biofield is a complex network of energies and information that direct cellular function and overall health. Pioneering research is exploring the biofield using concepts from physics, investigating phenomena like biophotons, electromagnetic fields, and quantum effects in tissues. This research may lead to more effective, non-invasive medical therapies based on correcting distortions in a person's biofield through various energy and information-based mechanisms.
Pranic healing is an ancient energy healing technique that utilizes life energy or prana to accelerate the body's natural healing process without physical contact. It balances, harmonizes, and transforms the body's energy to heal ailments. Pranic healing can be learned through standardized modules taught over multiple levels, with the first level focusing on basic principles and techniques to treat simple physical ailments. Scientific instruments have detected bioenergy fields around the human body that change with health and emotional states, supporting the idea of energy fields that pranic healing aims to balance and transform for healing.
Physiological Effects Of Microcurrent On The Body Peter Lathropdrpeterlathrop
Microcurrent therapy involves applying a very low electric current (in the microamp range) to the body. This current mimics the body's natural bioelectric currents and stimulates cellular physiology and growth. One study showed microcurrent increased ATP generation by 500%. Microcurrent enhances the body's natural healing processes by increasing ATP, membrane transport of ions, and protein synthesis. It reduces tissue resistance, allowing bioelectricity to flow and restore homeostasis after injury or dysfunction.
Scientists revived a giant virus that was buried in Siberian ice for 30,000 years. The virus, called Pithovirus, replicates by copying itself in the host cell's cytoplasm. The Human Genome Project aimed to sequence the three billion DNA bases in the human cell, which was completed in 2003 and provided new insights into diagnosing and treating human diseases. John Craig Venter founded Celera Genomics, the first private group to sequence the human genome using a "shotgun method" that helped complete the project. Biology is the study of life through structures, functions, and relationships of living things and their environment.
The document discusses the healing power of reciting the Quran. It provides several cases where reciting specific Quran verses cured illnesses. It explains that every verse contains a healing power for certain diseases if recited a specific number of times. Each cell vibrates at a precise frequency, and sound waves from reciting the Quran can restore balance to damaged cells. Several scientific studies are cited showing how sound therapies work and the unique impact of human voice. Reciting Quran modifies the electromagnetic fields in brain cells to change their vibrations and restore health.
This document provides an overview of the history and principles of radionics. It discusses key figures who contributed to the development of radionics such as Dr. Abrams in the 1920s who first identified diseases by measuring resistance in the body. It explains that radionics recognizes that all life forms share a common electromagnetic field and vibrate at unique frequencies. It describes how radionics works using instruments to detect imbalances and send correcting frequencies to treat diseases remotely. The document also discusses morphogenetic fields and how radionics can scan and instruct these fields to induce desired changes in living systems.
Magnetic resonance imaging (MRI) uses strong magnetic fields and radio waves to produce detailed images of the inside of the body. Dr. Raymond Damadian discovered in the 1970s that MRI could distinguish between healthy and cancerous tissue, and he filed the first patent for using MRI for medical diagnosis. An MRI scanner aligns hydrogen atoms in the body with a strong magnetic field and uses radio waves to flip their spins, and sensors detect the radio signal emitted as the spins return to normal, allowing an image of tissues and structures to be produced. MRI is used to diagnose conditions like tumors, strokes, and musculoskeletal disorders.
Picturing Science: An overview of Imaging TechnologiesDr. Sima Salahshor
In the past decades imaging technologies are increasingly used to model the dynamics and structure of biological systems. Biomedical imaging is now an integral part of biological and medical sciences and is used in both clinical practice and research. In this session some of the latest imaging technologies were reviewed.
Pranic Healing is a no-touch energy healing technique that uses prana or life energy to balance the body's energy processes and accelerate healing. It is based on ancient healing arts that utilized energy fields. Pranic Healing can be learned through standardized training modules and involves techniques like energy cleansing and energizing to increase healing rates. Research has shown that all living things, including humans, have measurable bioenergy fields that interact and can be influenced to support health and well-being.
The document defines anatomy and its main subdivisions:
1) Gross anatomy includes regional, systemic, and surface anatomy.
2) Microscopic anatomy includes cytology and histology.
3) Developmental anatomy includes embryology and fetology.
4) Pathological anatomy studies structural changes during disease.
5) Radiographic anatomy uses imaging techniques like X-rays and MRI to study body structures.
Quantum resonance magnetic analyzer presentation dr kamaljit singhDr Kamaljit Singh
"Prevention is Better than Cure"
Your Health Status in one Minute with this Hi-Tech Quantum Resonance Magnetic Analyzer;Multiple approx indicators of health can be obtained within minutes. This analysis method is designed to save your time and energy. The database of the analysis system has been established with scientific method, strict health statistic treatment and demonstration of a large number of clinical cases, leading thus to analysis .
By holding the sensor in your palm, hundreds of health data will be obtained within minutes from your body. This is absolutely not science fiction; It is the epoch-making high-tech quantum resonant magnetic analyzer.The main analysis items are over 37, including cardiovascular and cerebrovascular condition, bone mineral density, trace elements, blood lead, rheumatism, lung and respiratory tract, nephropathy, blood sugar, stomach and intestines, liver and gall, cranial nerves, gynecology, prostate, bone disease, the trace elements of selenium, iron, zinc and calcium, etc.
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Applications of physics in biology
1. What is Physics?
What is Biology?
Natural Biology
Basic Biology
Biology and Physics Work Together
Applications of Biophysics in Ecosystem
CONTENTS
2. Homeostasis Law of Thermodynamics
Excitable membrane
Movement of organisms
Sound production
Gravity
Medical
CONTENTS
3. WHAT IS PHYSICS?
Physics is the study of
energy and matter and
how the two interact
through time and space.
4. “Biology is the study of
life and organisms”.
“Bio” means life and
“logy” means study.
WHAT IS BIOLOGY?
5. Origin, evolution, function,
structure and distribution of living
organisms. Classification of
organisms, an organism’s ability to
regulate its internal environment.
NATURAL SCIENCE
6. Physics provides the basis for biology.
Without space, matter, energy and
time components that make up the
universe living organisms would not
exist.
Biology + Physics
Working Together
7. Physics helps explain how bats use
sound waves to navigate in the dark
How wings give insects the ability to
move through the air.
In some cases, biology helps prove
physical laws and theories.
Feynman states that biology helped
scientists come up with the law of
conservation of energy.
EXAMPLE
8.
9. IN ECOSYSTEM
According to the law of conservation of energy, energy is neither
created or destroyed but can be transformed from one state to
another state.
Energy of sunlight can be converted into energy of food and heat.
10. IN ECOSYSTEM
Contd…
According to the second law, no transfer of energy
occurs unless and until it is accompanied by
degradation or dissipation of energy from concentrated
to dispersed form.
So, the transfer of energy from one organism to
another is accompanied by degradation and loss of
major part of food energy as heat.
This is the reason that energy flow in ecosystem follows
10% law.
11.
12. HOMEOSTASIS & THE 1ST LAW OF THEMODYNAMICS
Metabolism converts foods
potential energy to both work and
heat energy, which are needed to
maintain a proper body
temperature and to do physical
activities.
13. EXCITABLE MEMBRANES
Signal-mediating cells of the nervous system called
neurons are special, in that they are able to send signals
to one another with velocities.
Resting potential
Driving forces due to the
electric field and the
concentration gradient and
mutually opposed,
there will be equilibrium.
14. MOVEMENT OF ORGANISMS
Movement in Bacteria
For small sizes of single cellular organisms
such as bacteria it is very difficult to move
as compared to the cases of swimming fish
and humans.
In this case viscosity plays a dominant role.
So, this results in evolution of bacteria in
flagella.
15. SOUND PRODUCTION
Human voice is produced in the
larynx, which is a part of the
throat.
When air from our lungs passes
through the tightened cords, a
vibration is produced.
This vibration produces vocal
sounds.
16. X-rays
Fluoroscopy
Mammography
Ultrasound
Lasers
Nuclear Medicine
MRI
Many Other Applications
17. X-Rays use high frequency electromagnetic
waves to pass through muscle and tissue to
generate 3D images of the body and if
they’re passed through an x-ray detector
outside of the body they can also detect
shadows that indicate abnormalities.
X-rays are best used to detect
abnormalities like bone fractures, tumors
and other abnormal masses, pneumonia,
calcifications, foreign objects, and dental
problems.
X-RAYS
18. FLOUROSCOPY and MRI
Fluoroscopy is a study of moving body structures--similar to
an X-ray "movie." A continuous X-ray beam is passed through
the body part being examined. The beam is transmitted to a
TV-like monitor so that the body part and its motion can be
seen in detail.
MRI(magnetic resonance imaging)
MRI is a test uses a magnetic field and pulses of radio
wave energy to make pictures of organism and structure
inside the body.
19. ULTRASOUND and MAMOGRAPHY
Medical sonography (ultrasonography) is an ultrasound-
based diagnostic medical imaging technique used to
visualize muscles, tendons, and many internal organs, to
capture their size, structure and any pathological lesions
with real time tomographic images.
Mammography is an X-ray picture of the cancer cells. It can
be used to check for breast cancer in women who have no
sign of the diseases.
20. It uses gamma-emitting radiotracers for single-
photon emission tomography, or SPECT scans.
NUCLEAR MEDICINE
LASER
Laser is high frequency beam of light
no of waves per unit area per unit time
21. Use a gamma camera to record images at a series of angles around the
patient, then reconstruct them to produce 3D cross-sectioned images of
organs and how they’re functioning in the body.
Areas of your brain are more or less active.
Detect brain disorders (dementia, clogged
blood vessels head injuries).
Detecting heart problems (clogged arteries
and reduced pumping efficiency).
Bone disorders (hidden fractures or tumors).
SPECT SCANS
22. Athene Donalds Friday 17,august 2012
Muskegon Community College: What it Biology?
Norwegian University of Science and Technology: What is Physics?
California Institute of Technology: The Feynman Lectures on
Physics, Volume I, Atoms in Motion
Physics.org: Keep Your Ears Peeled
Royal Society Publishing: Biology and Physics of Locust Flight. I,
Basic Principles in Insect Flight, A Critical Review
REFRENCES